If you know that your numbers are multiples of e.g. 0.01, I would suggest that you convert to double, round to the nearest integer, and subtract that to get the fractional residue. Multiply that by 100, round to the nearest integer, and then divide by 100. Add that to the whole-number part to get the nearest `double`

representation to the multiple of 0.01 which is nearest the original number.

Note that depending upon where the `float`

values originally came from, such treatment may or may not improve accuracy. The closest `float`

value to 9000.02 is about 9000.019531, and the closest `float`

value to 9000.021 is about 9000.021484f. If the values were arrived at by converting 9000.020 and 9000.021 to `float`

, the difference between them should be about 0.01. If, however, they were arrived at by e.g. computing `9000f+0.019531f`

and `9000f+0.021484f`

, then the difference between them should be closer to 0.02. Rounding to the nearest 0.01 before the subtract would improve accuracy in the former case and degrade it in the latter.

exactlyas a binary floating-point number, so it gives you the closest value it can.doingwith those numbers? Yes, converting a single to a string and parsing to a double is probably not the best approach.`Single`

to`Double`

while maintaining representability in case the value was indeed hard-coded, as the values are serialized at some point. I think I understand that direct`Single`

to`Double`

conversion is not harmful, but this is an issue of presentation.6more comments